source/opt/def_use_manager.h - external/github.com/KhronosGroup/SPIRV-Tools - Git at Google

 // Copyright (c) 2016 Google Inc.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #ifndef SOURCE_OPT_DEF_USE_MANAGER_H_
 #define SOURCE_OPT_DEF_USE_MANAGER_H_

 #include <list>
 #include <set>
 #include <unordered_map>
 #include <utility>
 #include <vector>

 #include "source/opt/instruction.h"
 #include "source/opt/module.h"
 #include "spirv-tools/libspirv.hpp"

 namespace spvtools {
 namespace opt {
 namespace analysis {

 // Class for representing a use of id. Note that:
 // * Result type id is a use.
 // * Ids referenced in OpSectionMerge & OpLoopMerge are considered as use.
 // * Ids referenced in OpPhi's in operands are considered as use.
 struct Use {
   Instruction* inst;       // Instruction using the id.
   uint32_t operand_index;  // logical operand index of the id use. This can be
                            // the index of result type id.
 };

 inline bool operator==(const Use& lhs, const Use& rhs) {
   return lhs.inst == rhs.inst && lhs.operand_index == rhs.operand_index;
 }

 inline bool operator!=(const Use& lhs, const Use& rhs) { return !(lhs == rhs); }

 inline bool operator<(const Use& lhs, const Use& rhs) {
   if (lhs.inst < rhs.inst) return true;
   if (lhs.inst > rhs.inst) return false;
   return lhs.operand_index < rhs.operand_index;
 }

 // Definition and user pair.
 //
 // The first element of the pair is the definition.
 // The second element of the pair is the user.
 //
 // Definition should never be null. User can be null, however, such an entry
 // should be used only for searching (e.g. all users of a particular definition)
 // and never stored in a container.
 using UserEntry = std::pair<Instruction*, Instruction*>;

 // Orders UserEntry for use in associative containers (i.e. less than ordering).
 //
 // The definition of an UserEntry is treated as the major key and the users as
 // the minor key so that all the users of a particular definition are
 // consecutive in a container.
 //
 // A null user always compares less than a real user. This is done to provide
 // easy values to search for the beginning of the users of a particular
 // definition (i.e. using {def, nullptr}).
 struct UserEntryLess {
   bool operator()(const UserEntry& lhs, const UserEntry& rhs) const {
     // If lhs.first and rhs.first are both null, fall through to checking the
     // second entries.
     if (!lhs.first && rhs.first) return true;
     if (lhs.first && !rhs.first) return false;

     // If neither definition is null, then compare unique ids.
     if (lhs.first && rhs.first) {
       if (lhs.first->unique_id() < rhs.first->unique_id()) return true;
       if (rhs.first->unique_id() < lhs.first->unique_id()) return false;
     }

     // Return false on equality.
     if (!lhs.second && !rhs.second) return false;
     if (!lhs.second) return true;
     if (!rhs.second) return false;

     // If neither user is null then compare unique ids.
     return lhs.second->unique_id() < rhs.second->unique_id();
   }
 };

 // A class for analyzing and managing defs and uses in an Module.
 class DefUseManager {
  public:
   using IdToDefMap = std::unordered_map<uint32_t, Instruction*>;
   using IdToUsersMap = std::set<UserEntry, UserEntryLess>;

   // Constructs a def-use manager from the given |module|. All internal messages
   // will be communicated to the outside via the given message |consumer|. This
   // instance only keeps a reference to the |consumer|, so the |consumer| should
   // outlive this instance.
   DefUseManager(Module* module) { AnalyzeDefUse(module); }

   DefUseManager(const DefUseManager&) = delete;
   DefUseManager(DefUseManager&&) = delete;
   DefUseManager& operator=(const DefUseManager&) = delete;
   DefUseManager& operator=(DefUseManager&&) = delete;

   // Analyzes the defs in the given |inst|.
   void AnalyzeInstDef(Instruction* inst);

   // Analyzes the uses in the given |inst|.
   //
   // All operands of |inst| must be analyzed as defs.
   void AnalyzeInstUse(Instruction* inst);

   // Analyzes the defs and uses in the given |inst|.
   void AnalyzeInstDefUse(Instruction* inst);

   // Returns the def instruction for the given |id|. If there is no instruction
   // defining |id|, returns nullptr.
   Instruction* GetDef(uint32_t id);
   const Instruction* GetDef(uint32_t id) const;

   // Runs the given function |f| on each unique user instruction of |def| (or
   // |id|).
   //
   // If one instruction uses |def| in multiple operands, that instruction will
   // only be visited once.
   //
   // |def| (or |id|) must be registered as a definition.
   void ForEachUser(const Instruction* def,
                    const std::function<void(Instruction*)>& f) const;
   void ForEachUser(uint32_t id,
                    const std::function<void(Instruction*)>& f) const;

   // Runs the given function |f| on each unique user instruction of |def| (or
   // |id|). If |f| returns false, iteration is terminated and this function
   // returns false.
   //
   // If one instruction uses |def| in multiple operands, that instruction will
   // be only be visited once.
   //
   // |def| (or |id|) must be registered as a definition.
   bool WhileEachUser(const Instruction* def,
                      const std::function<bool(Instruction*)>& f) const;
   bool WhileEachUser(uint32_t id,
                      const std::function<bool(Instruction*)>& f) const;

   // Runs the given function |f| on each unique use of |def| (or
   // |id|).
   //
   // If one instruction uses |def| in multiple operands, each operand will be
   // visited separately.
   //
   // |def| (or |id|) must be registered as a definition.
   void ForEachUse(
       const Instruction* def,
       const std::function<void(Instruction*, uint32_t operand_index)>& f) const;
   void ForEachUse(
       uint32_t id,
       const std::function<void(Instruction*, uint32_t operand_index)>& f) const;

   // Runs the given function |f| on each unique use of |def| (or
   // |id|). If |f| returns false, iteration is terminated and this function
   // returns false.
   //
   // If one instruction uses |def| in multiple operands, each operand will be
   // visited separately.
   //
   // |def| (or |id|) must be registered as a definition.
   bool WhileEachUse(
       const Instruction* def,
       const std::function<bool(Instruction*, uint32_t operand_index)>& f) const;
   bool WhileEachUse(
       uint32_t id,
       const std::function<bool(Instruction*, uint32_t operand_index)>& f) const;

   // Returns the number of users of |def| (or |id|).
   uint32_t NumUsers(const Instruction* def) const;
   uint32_t NumUsers(uint32_t id) const;

   // Returns the number of uses of |def| (or |id|).
   uint32_t NumUses(const Instruction* def) const;
   uint32_t NumUses(uint32_t id) const;

   // Returns the annotation instrunctions which are a direct use of the given
   // |id|. This means when the decorations are applied through decoration
   // group(s), this function will just return the OpGroupDecorate
   // instrcution(s) which refer to the given id as an operand. The OpDecorate
   // instructions which decorate the decoration group will not be returned.
   std::vector<Instruction*> GetAnnotations(uint32_t id) const;

   // Returns the map from ids to their def instructions.
   const IdToDefMap& id_to_defs() const { return id_to_def_; }
   // Returns the map from instructions to their users.
   const IdToUsersMap& id_to_users() const { return id_to_users_; }

   // Clear the internal def-use record of the given instruction |inst|. This
   // method will update the use information of the operand ids of |inst|. The
   // record: |inst| uses an |id|, will be removed from the use records of |id|.
   // If |inst| defines an result id, the use record of this result id will also
   // be removed. Does nothing if |inst| was not analyzed before.
   void ClearInst(Instruction* inst);

   // Erases the records that a given instruction uses its operand ids.
   void EraseUseRecordsOfOperandIds(const Instruction* inst);

   friend bool operator==(const DefUseManager&, const DefUseManager&);
   friend bool operator!=(const DefUseManager& lhs, const DefUseManager& rhs) {
     return !(lhs == rhs);
   }

   // If |inst| has not already been analysed, then analyses its defintion and
   // uses.
   void UpdateDefUse(Instruction* inst);

  private:
   using InstToUsedIdsMap =
       std::unordered_map<const Instruction*, std::vector<uint32_t>>;

   // Returns the first location that {|def|, nullptr} could be inserted into the
   // users map without violating ordering.
   IdToUsersMap::const_iterator UsersBegin(const Instruction* def) const;

   // Returns true if |iter| has not reached the end of |def|'s users.
   //
   // In the first version |iter| is compared against the end of the map for
   // validity before other checks. In the second version, |iter| is compared
   // against |cached_end| for validity before other checks. This allows caching
   // the map's end which is a performance improvement on some platforms.
   bool UsersNotEnd(const IdToUsersMap::const_iterator& iter,
                    const Instruction* def) const;
   bool UsersNotEnd(const IdToUsersMap::const_iterator& iter,
                    const IdToUsersMap::const_iterator& cached_end,
                    const Instruction* def) const;

   // Analyzes the defs and uses in the given |module| and populates data
   // structures in this class. Does nothing if |module| is nullptr.
   void AnalyzeDefUse(Module* module);

   IdToDefMap id_to_def_;      // Mapping from ids to their definitions
   IdToUsersMap id_to_users_;  // Mapping from ids to their users
   // Mapping from instructions to the ids used in the instruction.
   InstToUsedIdsMap inst_to_used_ids_;
 };

 }  // namespace analysis
 }  // namespace opt
 }  // namespace spvtools

 #endif  // SOURCE_OPT_DEF_USE_MANAGER_H_
	// Copyright (c) 2016 Google Inc.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#ifndef SOURCE_OPT_DEF_USE_MANAGER_H_
	#define SOURCE_OPT_DEF_USE_MANAGER_H_

	#include <list>
	#include <set>
	#include <unordered_map>
	#include <utility>
	#include <vector>

	#include "source/opt/instruction.h"
	#include "source/opt/module.h"
	#include "spirv-tools/libspirv.hpp"

	namespace spvtools {
	namespace opt {
	namespace analysis {

	// Class for representing a use of id. Note that:
	// * Result type id is a use.
	// * Ids referenced in OpSectionMerge & OpLoopMerge are considered as use.
	// * Ids referenced in OpPhi's in operands are considered as use.
	struct Use {
	Instruction* inst; // Instruction using the id.
	uint32_t operand_index; // logical operand index of the id use. This can be
	// the index of result type id.
	};

	inline bool operator==(const Use& lhs, const Use& rhs) {
	return lhs.inst == rhs.inst && lhs.operand_index == rhs.operand_index;
	}

	inline bool operator!=(const Use& lhs, const Use& rhs) { return !(lhs == rhs); }

	inline bool operator<(const Use& lhs, const Use& rhs) {
	if (lhs.inst < rhs.inst) return true;
	if (lhs.inst > rhs.inst) return false;
	return lhs.operand_index < rhs.operand_index;
	}

	// Definition and user pair.
	//
	// The first element of the pair is the definition.
	// The second element of the pair is the user.
	//
	// Definition should never be null. User can be null, however, such an entry
	// should be used only for searching (e.g. all users of a particular definition)
	// and never stored in a container.
	using UserEntry = std::pair<Instruction, Instruction>;

	// Orders UserEntry for use in associative containers (i.e. less than ordering).
	//
	// The definition of an UserEntry is treated as the major key and the users as
	// the minor key so that all the users of a particular definition are
	// consecutive in a container.
	//
	// A null user always compares less than a real user. This is done to provide
	// easy values to search for the beginning of the users of a particular
	// definition (i.e. using {def, nullptr}).
	struct UserEntryLess {
	bool operator()(const UserEntry& lhs, const UserEntry& rhs) const {
	// If lhs.first and rhs.first are both null, fall through to checking the
	// second entries.
	if (!lhs.first && rhs.first) return true;
	if (lhs.first && !rhs.first) return false;

	// If neither definition is null, then compare unique ids.
	if (lhs.first && rhs.first) {
	if (lhs.first->unique_id() < rhs.first->unique_id()) return true;
	if (rhs.first->unique_id() < lhs.first->unique_id()) return false;
	}

	// Return false on equality.
	if (!lhs.second && !rhs.second) return false;
	if (!lhs.second) return true;
	if (!rhs.second) return false;

	// If neither user is null then compare unique ids.
	return lhs.second->unique_id() < rhs.second->unique_id();
	}
	};

	// A class for analyzing and managing defs and uses in an Module.
	class DefUseManager {
	public:
	using IdToDefMap = std::unordered_map<uint32_t, Instruction*>;
	using IdToUsersMap = std::set<UserEntry, UserEntryLess>;

	// Constructs a def-use manager from the given \|module\|. All internal messages
	// will be communicated to the outside via the given message \|consumer\|. This
	// instance only keeps a reference to the \|consumer\|, so the \|consumer\| should
	// outlive this instance.
	DefUseManager(Module* module) { AnalyzeDefUse(module); }

	DefUseManager(const DefUseManager&) = delete;
	DefUseManager(DefUseManager&&) = delete;
	DefUseManager& operator=(const DefUseManager&) = delete;
	DefUseManager& operator=(DefUseManager&&) = delete;

	// Analyzes the defs in the given \|inst\|.
	void AnalyzeInstDef(Instruction* inst);

	// Analyzes the uses in the given \|inst\|.
	//
	// All operands of \|inst\| must be analyzed as defs.
	void AnalyzeInstUse(Instruction* inst);

	// Analyzes the defs and uses in the given \|inst\|.
	void AnalyzeInstDefUse(Instruction* inst);

	// Returns the def instruction for the given \|id\|. If there is no instruction
	// defining \|id\|, returns nullptr.
	Instruction* GetDef(uint32_t id);
	const Instruction* GetDef(uint32_t id) const;

	// Runs the given function \|f\| on each unique user instruction of \|def\| (or
	// \|id\|).
	//
	// If one instruction uses \|def\| in multiple operands, that instruction will
	// only be visited once.
	//
	// \|def\| (or \|id\|) must be registered as a definition.
	void ForEachUser(const Instruction* def,
	const std::function<void(Instruction*)>& f) const;
	void ForEachUser(uint32_t id,
	const std::function<void(Instruction*)>& f) const;

	// Runs the given function \|f\| on each unique user instruction of \|def\| (or
	// \|id\|). If \|f\| returns false, iteration is terminated and this function
	// returns false.
	//
	// If one instruction uses \|def\| in multiple operands, that instruction will
	// be only be visited once.
	//
	// \|def\| (or \|id\|) must be registered as a definition.
	bool WhileEachUser(const Instruction* def,
	const std::function<bool(Instruction*)>& f) const;
	bool WhileEachUser(uint32_t id,
	const std::function<bool(Instruction*)>& f) const;

	// Runs the given function \|f\| on each unique use of \|def\| (or
	// \|id\|).
	//
	// If one instruction uses \|def\| in multiple operands, each operand will be
	// visited separately.
	//
	// \|def\| (or \|id\|) must be registered as a definition.
	void ForEachUse(
	const Instruction* def,
	const std::function<void(Instruction*, uint32_t operand_index)>& f) const;
	void ForEachUse(
	uint32_t id,
	const std::function<void(Instruction*, uint32_t operand_index)>& f) const;

	// Runs the given function \|f\| on each unique use of \|def\| (or
	// \|id\|). If \|f\| returns false, iteration is terminated and this function
	// returns false.
	//
	// If one instruction uses \|def\| in multiple operands, each operand will be
	// visited separately.
	//
	// \|def\| (or \|id\|) must be registered as a definition.
	bool WhileEachUse(
	const Instruction* def,
	const std::function<bool(Instruction*, uint32_t operand_index)>& f) const;
	bool WhileEachUse(
	uint32_t id,
	const std::function<bool(Instruction*, uint32_t operand_index)>& f) const;

	// Returns the number of users of \|def\| (or \|id\|).
	uint32_t NumUsers(const Instruction* def) const;
	uint32_t NumUsers(uint32_t id) const;

	// Returns the number of uses of \|def\| (or \|id\|).
	uint32_t NumUses(const Instruction* def) const;
	uint32_t NumUses(uint32_t id) const;

	// Returns the annotation instrunctions which are a direct use of the given
	// \|id\|. This means when the decorations are applied through decoration
	// group(s), this function will just return the OpGroupDecorate
	// instrcution(s) which refer to the given id as an operand. The OpDecorate
	// instructions which decorate the decoration group will not be returned.
	std::vector<Instruction*> GetAnnotations(uint32_t id) const;

	// Returns the map from ids to their def instructions.
	const IdToDefMap& id_to_defs() const { return id_to_def_; }
	// Returns the map from instructions to their users.
	const IdToUsersMap& id_to_users() const { return id_to_users_; }

	// Clear the internal def-use record of the given instruction \|inst\|. This
	// method will update the use information of the operand ids of \|inst\|. The
	// record: \|inst\| uses an \|id\|, will be removed from the use records of \|id\|.
	// If \|inst\| defines an result id, the use record of this result id will also
	// be removed. Does nothing if \|inst\| was not analyzed before.
	void ClearInst(Instruction* inst);

	// Erases the records that a given instruction uses its operand ids.
	void EraseUseRecordsOfOperandIds(const Instruction* inst);

	friend bool operator==(const DefUseManager&, const DefUseManager&);
	friend bool operator!=(const DefUseManager& lhs, const DefUseManager& rhs) {
	return !(lhs == rhs);
	}

	// If \|inst\| has not already been analysed, then analyses its defintion and
	// uses.
	void UpdateDefUse(Instruction* inst);

	private:
	using InstToUsedIdsMap =
	std::unordered_map<const Instruction*, std::vector<uint32_t>>;

	// Returns the first location that {\|def\|, nullptr} could be inserted into the
	// users map without violating ordering.
	IdToUsersMap::const_iterator UsersBegin(const Instruction* def) const;

	// Returns true if \|iter\| has not reached the end of \|def\|'s users.
	//
	// In the first version \|iter\| is compared against the end of the map for
	// validity before other checks. In the second version, \|iter\| is compared
	// against \|cached_end\| for validity before other checks. This allows caching
	// the map's end which is a performance improvement on some platforms.
	bool UsersNotEnd(const IdToUsersMap::const_iterator& iter,
	const Instruction* def) const;
	bool UsersNotEnd(const IdToUsersMap::const_iterator& iter,
	const IdToUsersMap::const_iterator& cached_end,
	const Instruction* def) const;

	// Analyzes the defs and uses in the given \|module\| and populates data
	// structures in this class. Does nothing if \|module\| is nullptr.
	void AnalyzeDefUse(Module* module);

	IdToDefMap id_to_def_; // Mapping from ids to their definitions
	IdToUsersMap id_to_users_; // Mapping from ids to their users
	// Mapping from instructions to the ids used in the instruction.
	InstToUsedIdsMap inst_to_used_ids_;
	};

	} // namespace analysis
	} // namespace opt
	} // namespace spvtools

	#endif // SOURCE_OPT_DEF_USE_MANAGER_H_